Device and method for monitoring inhibition of platelet function

ABSTRACT

The invention provides a method of monitoring the response of platelets to a cyclooxygenase-1 (COX1) inhibitor such as aspirin. The method involves collecting platelet-containing mammalian blood treated with a COX1 inhibitor; mixing the blood with a COX1-dependent platelet agonist, such as arachidonic acid, monitoring extracellular ATP in the agonist-activated blood to generate a measurement, and comparing the measurement to a standard value. Devices, systems, and kits for carrying out the method are also provided.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No. 12/052,363, filed Mar. 20, 2008 (to issue as U.S. Pat. No. 7,833,793 on Nov. 16, 2010), which is a continuation of U.S. patent application Ser. No. 10/846,439, filed May 14, 2004, both of which are hereby incorporated by reference in their entirety.

FIELD OF THE INVENTION

This invention relates generally to physiological analysis and more particularly to a method to measure inhibition of platelet function by aspirin or another cyclooxygenase-1 inhibitor.

BACKGROUND OF THE INVENTION

Millions of people are taking aspirin as therapy to reduce the risk of heart attacks and other cardiovascular events. These include persons with elevated cholesterol, a family history of heart disease, or other risk factors for cardiovascular disease. Among those with risk factors, nearly all persons with implanted cardiovascular devices are at elevated risk of clot formation and embolization and are prescribed some anti-platelet agent, usually aspirin. In addition, many healthy people without a recognized elevated risk of cardiovascular disease also take aspirin as a precaution.

Platelets function to stop bleeding by forming clots, and initiate the process of wound healing. This occurs when platelets are activated, causing them to change shape, adhere, spread, release chemical messengers and activators, aggregate, and assemble with fibrin.

But platelet activation and clot formation can also place a person at risk of pathological cardiovascular events. For example, venous blood clot formation in the legs, a condition known as deep vein thrombosis, creates the risk that the blood clots could embolize (break apart) and result in clot entrapment in the lungs or the brain, causing pulmonary embolisms and stroke-related conditions. Platelet activation and fibrin formation in other locations in some persons create aggregates and small clots in the arterial circulation that can also lead to embolization and strokes.

Each year, approximately 500,000 heart valves are implanted in the United States. Although biomaterial advancement has somewhat reduced the risk of thrombosis (clot formation), all patients with mechanical heart valves are at increased risk of clot formation, embolization, and stroke, and are usually placed on aspirin therapy.

Arterial stents are another type of device placed in the circulatory system that place patients at risk from platelet activation. Arterial stents are placed in clogged coronary and carotid arteries to provide oxygen to cardiac tissue. They are typically around 5 mm in diameter and are made from stainless steel or other materials. Due to the introduction of a foreign material in the blood stream, platelets can become activated and attach to the wall of the stented vessel. This leads to reocclusion (restenosis) of the stented vessel, which is a very significant risk in patients with arterial stents. Restenosis in the first 28 days is reported in 0.5 to 8% of persons receiving stents.

To reduce these and other risks of cardiovascular pathology, millions of patients are placed on anti-platelet drugs, most commonly aspirin.

It is useful here to briefly summarize the biochemical events of hemostasis (the cessation of bleeding) and aspirin's role in inhibiting the process. Normal intact vascular endothelium does not initiate or support platelet adhesion (although in certain vascular diseases platelets may adhere to intact endothelium). Vascular injury, however, exposes the endothelial surface and underlying collagen. Following vascular injury, platelets attach to adhesive proteins such as collagen via specific glycoproteins on the platelet surface. This adhesion is followed or accompanied by platelet activation, where platelets undergo a shape change from a disc shape to a spherical shape with extended pseudopodia. At this time, the platelet release reaction also occurs. The platelets release biologically active compounds stored in the cytoplasmic bodies that stimulate platelet activation or are otherwise involved in clotting reactions. These include ADP, serotonin, thromboxane A₂, and von Willebrand factor.

Following activation, glycoprotein receptors on the surface of the platelets undergo a conformational change from a relatively inactive conformation to an activated form. The activated receptors mediate the adhesion of more platelets by adhering to the circulating plasma protein fibrinogen, which serves as a bridging ligand between platelets. The adhesion and aggregation of platelets constitutes primary hemostasis.

Secondary hemostasis stabilizes the platelet mass by forming a fibrin clot. The fibrin clot is the end product of a series of reactions involving plasma proteins. The process is known as blood coagulation. In coagulation, fibrin is formed from fibrinogen, a large circulating plasma protein, by specific proteolysis. In the process, the protein thrombin is consumed. Fibrin monomers next spontaneously associate to form polymers and form a loose reinforcement of the platelet plug. Fibrin polymers are then cross-linked by certain enzymes. The fibrin polymer also traps red cells and white cells to form a finished clot.

Platelets are activated by a variety of stimuli. Collagen, ADP, thrombin, and physical shear stress all activate platelets. One of the first steps in activation is that a platelet membrane phospholipase, phospholipase A₂, cleaves membrane lipids to release the fatty acid arachidonic acid. Arachidonic acid is oxidized in the platelet by the enzyme cyclooxygenase to the prostaglandin PGG₂. PGG₂ can be enzymatically converted to PGH₂, and PGH₂ is converted by thromboxane synthetase to thromboxane A₂ (TxA₂).

TxA₂ is a very potent activator of platelets and greatly amplifies the platelet release reaction, where the platelets secrete the contents of certain cytoplasmic bodies, including alpha granules and dense bodies. Among the components secreted from dense bodies are ADP, Ca⁺⁺, Mg⁺⁺, and serotonin.

Aspirin acts by acetylating and inactivating cyclooxygenase-1 in platelets, preventing the synthesis of TxA₂. By preventing the synthesis of TxA₂, aspirin significantly reduces platelet activation and thus reduces clotting. Aspirin inactivates cyclooxygenase-1 (COX1) at a lower dose and more completely than it inactivates or inhibits another isoform of cyclooxygenase, cyclooxygenase-2. COX1 is the predominant cyclooxygenase in platelets. COX2 is involved in inflammation. (Vane, J. R., et al., 2003, The mechanism of action of aspirin, Thrombosis Research 110: 255.)

Thus, by inhibiting platelet activation, aspirin for most patients is an effective agent to prevent clots and pathological cardiovascular events. But many people are resistant to aspirin. In one study, 5.5% or 9.5% of patients were resistant to aspirin, as assayed by two different techniques, and 23.8% of patients were semi-resistant (Gum, P. A., et al., 2001, Am. J. Cardiology 88: 230). Other studies estimate 5-40% of patients are aspirin resistant, depending on the assay and the population studied (Bhatt, D. L., 2004, J. Am. College of Cardiology Vol. 43, No. 6, 2004). This is very important, because aspirin resistance is significantly associated with an increased risk of death, myocardial infarction, or cerebrovascular accident (Altman, R., et al., 2004, Thrombosis J. 2: 1).

It is important to identify patients resistant to aspirin or other COX1 inhibitors, because if they are identified they can be placed on other platelet inhibitors that act by a different mechanism. This is important not only for proper treatment of the patients, but also for cost savings. The other platelet inhibitors are much more expensive than aspirin, so it would be extremely expensive to indiscriminately prescribe them. (Other platelet inhibitors include ADP inhibitors such as ticlopidine, and monoclonal antibodies that block the GPIIbIIIa receptor such as RHEOPRO.) Physicians are only likely to prescribe them when it can be shown that aspirin is not working

Various techniques have been used to measure platelet function and aspirin resistance. Among these is platelet aggregation. In this technique, platelet-rich plasma was prepared from whole blood. ADP and arachidonic acid were added to activate the platelets. And aggregation of the platelets was measured by optical density changes. (Gum, P. A., et al., 2001, Am. J. Cardiology 88: 230.) Another technique uses a device named the platelet function analyzer-100 (PFA-100). The PFA-100 uses a disposable cartridge with an aperture cut into a collagen-coated membrane infused with either ADP or epinephrine. Whole blood (approximately 1 ml) is pumped through the aperture at high shear rate. The blood comes into contact with the membrane where platelets adhere and aggregate. A platelet plug forms, occluding the aperture and stopping blood flow. The closure time is a measure of platelet function. (Gum, P. A., et al., 2001, Am. J. Cardiology 88: 230.) Another device used to measure aspirin response is the Accumetrix VERIFYNOW Aspirin Assay (www.accumetrics.com/products/ultegra_asa.html). This product uses a turbidity-based optical detection system. The device contains fibrinogen-coated beads, and a platelet agonist. Blood is withdrawn, citrated, and then mixed with the coated beads and the agonist. Aggregation of the platelets to the beads is measured optically.

Prior tests for aspirin response have various drawbacks. Many use significant volumes of blood. Some require time-consuming and labor-consuming processing of the blood. And some measure adhesion and aggregation of the platelets, which are complex phenomena that are the end result of several interacting steps, rather than more directly measuring steps more directly related to aspirin's inhibition of cyclooxygenase.

A new method of monitoring aspirin response or response to other COX1 inhibitors is needed. Preferably, the method would use a small volume of blood (e.g., less than a drop), use unprocessed whole blood, be fast, and be relatively specific for the pathway inhibited by aspirin, the COX1 pathway.

BRIEF SUMMARY OF THE INVENTION

The invention involves a method to measure inhibition of platelet function by aspirin or another cyclooxygenase-1 inhibitor. Blood is withdrawn from a patient who has taken aspirin and mixed with a COX1-dependent platelet agonist, typically arachidonic acid, which is the substrate for the enzyme cyclooxygenase-1 in platelets. Arachidonic acid is converted in platelets by COX1 to PGG₂ and then to thromboxane A₂. Thromboxane A₂ is a potent activator of platelets and instigates the platelet release reaction, where the platelets secrete the contents of their dense bodies and alpha granules. One of the compounds secreted from the dense bodies is ATP. In the present method, the secreted extracellular ATP or other extracellular platelet-release-reaction on product is detected, and its concentration is quantitatively or qualitatively determined. The result from the determination of the extracellular release-reaction product (e.g., ATP) concentration is compared with a standard, which can be the result from blood taken from the same patient before she or he took aspirin.

Aspirin acts by inactivating cyclooxygenase-1, the predominant cyclooxygenase in platelets. Thus, if aspirin has inactivated most or all cyclooxygenase-1, the amount of thromboxane A₂ produced will be decreased, the release reaction will be weaker, and less release reaction product (e.g., ATP) will be secreted, as compared to when the patient does not take aspirin.

The method can use less than a drop of blood. Whole blood can be used without any further processing. And results can be obtained at the patient's bedside in less than five minutes. In addition, since ATP release is strongly induced by thromboxane A₂, the assay has high specificity for the pathway inhibited by aspirin, the COX1 pathway: thromboxane A₂ synthesis from arachidonic acid.

In one embodiment, a finger prick is performed to draw a drop of blood from a patient who has not had aspirin or another COX1 inhibitor for at least several hours, preferably 8 days. (The lifetime of platelets is about 8 days. Aspirin covalently modifies the COX1 in platelets to inactivate it. So the effect of aspirin lingers until all the platelets inactivated by aspirin have been cleared. Other COX1 inhibitors may act by a noncovalent inhibition and have a shorter duration of action.) Approximately 10 μl of blood is taken and diluted 500:1 with buffer. The ATP-consuming and light-producing enzyme luciferase and its substrate luciferin are added, and a background reading of light emission is taken. Arachidonic acid is then added to the sample, and the increase in light emission is monitored. The patient then swallows aspirin, and the procedure is performed again, and the results compared. If the aspirin is working, there will be a large decrease in light emission in the blood sample drawn after the patient takes aspirin as compared to the sample drawn before the patient takes aspirin. If the patient is aspirin-resistant, the difference between the two results will be smaller.

Thus, one embodiment of the invention provides a method of monitoring COX1-inhibitor response involving: (a) collecting platelet-containing mammalian blood treated with a COX1inhibitor; (b) mixing the blood with a COX1-dependent platelet agonist to generate agonist-activated blood; (c) monitoring an extracellular platelet-release-reaction product (e.g. ATP) in the agonist-activated blood to generate a measurement; and (d) comparing the measurement to a standard value.

Another embodiment of the invention provides a device for monitoring COX1-inhibitor response including: (a) a fluid-tight material forming an assay chamber; (b) a pump functionally linked to the assay chamber for pumping fluids into the assay chamber; (c) a light detector functionally linked to the assay chamber for detecting light emitted in the assay chamber; (d) a fluid-tight material forming a blood chamber for holding blood, the blood chamber functionally linked to the pump; (e) a fluid-tight material forming an enzyme chamber for holding a solution of a light-producing ATP-consuming enzyme, the enzyme chamber functionally linked to the pump; and (f) a fluid-tight material forming an agonist chamber for holding a solution of a COX1-dependent platelet agonist, the agonist chamber functionally linked to the pump.

Another embodiment of the invention provides a system for monitoring COX1-inhibitor response including: (a) a fluid-tight material forming an assay chamber; (b) a pump functionally linked to the assay chamber for pumping fluids into the assay chamber; (c) a light detector functionally linked to the assay chamber for detecting light emitted in the assay chamber; (d) a fluid-tight material forming a blood chamber for holding blood, the blood chamber functionally linked to the pump; (e) a fluid-tight material forming an enzyme chamber for holding a solution of a light-producing ATP-consuming enzyme, the enzyme chamber functionally linked to the pump; (f) a fluid-tight material forming an agonist chamber for holding a solution of a COX1-dependent platelet agonist, the agonist chamber functionally linked to the pump; (g) a controller coupled to the pump and programmed to deliver to the assay chamber a predetermined volume of the blood, a predetermined volume of the light-producing enzyme solution, and a predetermined volume of the agonist solution; and (h) a display operably coupled to the photon counter for displaying results from the light detector.

Another embodiment of the invention provides a kit for determining response to a COX1 inhibitor containing: a COX1-dependent platelet agonist; an ATP-consuming enzyme; and instruction means indicating that the enzyme and the agonist are to be used to determine a subject mammal's physiological response to a COX1 inhibitor.

Another embodiment of the invention provides a kit for determining response to a COX1 inhibitor containing: (1) a device for monitoring COX1-inhibitor response comprising: (a) a fluid-tight material forming an assay chamber; (b) a pump functionally linked to the assay chamber for pumping fluids into the assay chamber; (c) a light detector functionally linked to the assay chamber for detecting light emitted in the assay chamber; (d) a fluid-tight material forming a blood chamber for holding blood, the blood chamber functionally linked to the pump; (e) a fluid-tight material forming an enzyme chamber for holding a solution of a light-producing ATP-consuming enzyme, the enzyme chamber functionally linked to the pump; and (f) a fluid-tight material forming an agonist chamber for holding a solution of a COX1-dependent platelet agonist, the agonist chamber functionally linked to the pump; and (2) instruction means indicating that the device is to be used to determine a subject mammal's physiological response to a COX1 inhibitor.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows the pathway of thromboxane A₂ synthesis from arachidonic acid.

FIGS. 2A-C show luciferase assay results with arachidonic-acid-treated diluted blood drawn from three individuals before and after taking aspirin. The light emission reflects extracellular ATP.

FIG. 3 is a schematic diagram of a device for monitoring COX1-inhibitor response.

FIG. 4 is a schematic diagram of a device for monitoring COX1-inhibitor response, where the device includes a valve.

FIG. 5 is a schematic diagram of a system for monitoring COX1-inhibitor response.

FIG. 6 is a diagram of an apparatus for monitoring aspirin response that pumps fluids into a cuvette.

DETAILED DESCRIPTION OF THE INVENTION

Definitions:

The term “COX1 inhibitor” refers to an agent that selectively inhibits COX1 more than it inhibits COX2 or inhibits COX1 at a lower concentration of agent than COX2. The inhibition can be due to covalent or noncovalent interactions. The inhibition can be inactivation, competitive, uncompetitive, or non-competitive inhibition. The most common COX1 inhibitor is aspirin. Another example of a COX1 inhibitor is SC-58560 (Bolla, M., et al., Hypertension, Apr. 19, 2004).

The term “platelet-containing blood” refers to whole blood or processed blood that contains platelets, e.g., platelet-rich plasma.

The terms “measurement” and “standard value” refer to quantitative or qualitative assessments that can be compared with each other.

The term “blood treated with a COX1 inhibitor” refers to blood contacted with a COX1 inhibitor either in vivo or ex situ. The blood can be contacted with the inhibitor (e.g., aspirin), e.g., by orally administering aspirin to the mammal, or by contacting blood with aspirin after withdrawing the blood from the mammal.

The term “dilution medium” refers to any suitable liquid for diluting blood. This typically is an aqueous solution that includes a pH buffer and solutes sufficient to maintain an appropriate osmoticum in the dilution buffer, such as phosphate buffered saline or HEPES/HANKS. Dilution medium, however, need not contain a pH buffer, and could be water or for instance, a salt or sucrose solution in water.

The term “ATP-consuming enzyme” refers to an enzyme that uses and consumes ATP as a substrate.

The term “chamber” refers to a vessel that contains fluids. The chamber can be substantially enclosed, or could be, for instance, a section of tubing in which liquid is held.

A “light detector” as used herein is any apparatus or component of an apparatus capable of qualitatively or, preferably, quantitatively determining the intensity of light or number of photons emitted in an assay chamber. An example of a light detector is a photon counter.

A “COX1-dependent platelet agonist” as used herein is an agonist whose activation of platelets is substantially inhibited by aspirin in aspirin-sensitive humans. Preferably, a COX1-dependent platelet agonist is an agonist that induces a maximal rate of extracellular ATP release in aspirin-sensitive humans in the assays described herein that is at least 5 times higher in non-aspirin-treated blood than in aspirin-treated blood. Conversely, a platelet agonist that is not COX1 dependent as used herein refers to an agonist whose activation of platelets is not substantially inhibited by aspirin in aspirin-sensitive humans. It induces a maximal rate of extracellular ATP release in aspirin-sensitive humans in the assays described herein that is less than 5 times higher, preferably less than 3 times higher, more preferably less than 2 times higher, most preferably approximately the same, in non-aspirin-treated blood than in aspirin-treated blood.

The most preferred COX1-dependent platelet agonist is arachidonic acid. The most preferred platelet agonist that is not COX1 dependent is thromboxane A₂. Other platelet agonists that are not COX1 dependent include collagen, thrombin, and ADP.

“An extracellular platelet-release-reaction product,” as used herein, is a component secreted from platelets in response to arachidonic acid, whose maximal rate of secretion in aspirin sensitive humans is at least 2 times faster before the person takes aspirin than the maximal rate of secretion after the person takes aspirin. Preferably, the platelet-release-reaction product is a product whose maximal rate of secretion is at least 3 times faster, more preferably at least 5 times faster, before the person takes aspirin than after the person takes aspirin. The extracellular platelet-release-reaction product may be soluble in the extracellular medium or may become exposed on the extracellular platelet membrane surface after the release reaction.

The preferred extracellular platelet-release-reaction product is ATP. Other examples of extracellular release reaction products include the dense body components GDP, GTP, ADP, serotonin, Mg⁺⁺, and Ca⁺⁺, as well as the alpha granule components fibrinogen, von Willebrand factor, fibronectin, thrombospondin, vitronectin, factor V, factor XI, protein S, platelet-derived growth factor, transforming growth factor β, epidermal growth factor, P-selectin, GMP 33, and osteonectin. (The Megakaryocyte-Platelet System, R. R. Rifkin, in Clinical Hematology: Principles, Procedures, Correlations, second edition, Stiene-Martin, E. A., et al., eds., Lippincott, N.Y., 1998.)

Description

The pathway of thromboxane A₂ synthesis from arachidonic acid in platelets is shown in FIG. 1. Aspirin inhibits this pathway by acetylating cyclooxygenase and inactivating the enzyme.

In one embodiment of the method of monitoring COX1-inhibitor response, the COX1 inhibitor is aspirin.

In one embodiment, the extracellular platelet-release-reaction product is ATP.

In one embodiment, the COX1-dependent platelet agonist is arachidonic acid.

Another example of a class of COX1-dependent platelet agonists is phospholipase A₂ activators. Compounds that activate phospholipase A₂ stimulate the release of arachidonic acid by the phospholipase A₂ in platelets.

Other specific examples of COX1-dependent platelet agonists include propyl gallate and U-46619 (Bolla, M. et al. Hypertension, Apr. 19, 2004.)

In one embodiment of the method of monitoring COX1-inhibitor response, the step of monitoring extracellular ATP involves adding to the blood an ATP-consuming enzyme that catalyzes a reaction, and monitoring the enzyme-catalyzed reaction.

In one embodiment, monitoring the enzyme-catalyzed reaction involves monitoring a product produced by the reaction. The product can be, for instance, light. In other embodiments, monitoring the reaction involves monitoring the disappearance of a reactant.

In one embodiment of the method using an enzyme, the enzyme is luciferase (e.g., firefly luciferase). In particular embodiments, the method further involves adding luciferin to the blood. In one embodiment, the luciferin is firefly luciferin.

The steps of the invention can be performed in any suitable order. For instance, in the embodiments that involve adding to the blood an ATP-consuming enzyme that catalyzes a reaction and monitoring the reaction, the enzyme can be added to the blood before, together with, or after the COX1-dependent agonist. Likewise, where another enzyme substrate such as luciferin is added, the substrate can be added before, together with, or after both the enzyme and the agonist.

In one particular embodiment, luciferin and luciferase are added to the blood before the blood is mixed with the COX1-dependent platelet agonist. In another particular embodiment, luciferin and luciferase are added to the blood after the blood is mixed with the agonist.

Particular embodiments of the method of the invention further involve diluting the blood.

In a particular embodiment where the blood is diluted, the step of monitoring extracellular ATP involves adding luciferin and luciferase to the blood, and monitoring light produced by the luciferase.

One of the advantages of the method of the invention is that small volumes of blood can be used. Blood can be collected by a finger prick, and less than a drop can be used. In particular embodiments, less than 120, less than 100, less than 75, less than 40, less than 20, less than 12, or less than 10 microliters are collected from the mammal. In other particular embodiments, less than 120, less than 100, less than 75, less than 40, less than 20, less than 12, or less than 10 microliters of blood is mixed with the COX1-dependent platelet agonist.

In particular embodiments, the mammal is a human.

In particular embodiments of the invention, the platelet-containing blood is whole blood.

One method of determining the standard value for comparison in the assay is to collect non-aspirin-treated blood (or blood not treated with a COX1 inhibitor) from the same mammalian subject, and perform the same assay on the non-aspirin-treated blood to generate a measurement to be used as the standard value. In these embodiments, the standard value is determined by a method involving collecting platelet-containing standard blood from the mammal; mixing the standard blood with the COX1-dependent platelet agonist to generate agonist-activated standard blood; and monitoring the extracellular platelet-release-reaction product (e.g., ATP) in the agonist-activated standard blood to generate the standard value; wherein the standard blood is not treated with the COX1 inhibitor. Preferably, the mammalian subject has not been treated with the COX1 inhibitor for at least 3 hours, more preferably at least 6 hours, more preferably at least 12 hours, and more preferably still at least 24 hours, and more preferably still at least 8 days before the blood is collected. If the COX1 inhibitor is aspirin, preferably the subject has not been treated with aspirin for at least 24 hours, more preferably for at least 3 days, more preferably still for at least 8 days before the blood is collected.

The standard value can be obtained also by assaying blood of subjects different from the subject whose COX1-inhibitor-treated blood is assayed, and establishing a typical measured value reflecting the extracellular platelet-release-reaction product in agonist-activated blood where the blood is not COX1-inhibitor treated or where the blood is from subjects either resistant or sensitive to the COX1 inhibitor.

The measurement and standard value can be quantitative or qualitative, and can be time courses or individual time points. For instance, the measurement and standard value can be direct measurements of extracellular ATP concentration at a certain time point after mixing the blood with the agonist. They can also be time courses of light emission using luciferin or luciferase or individual time points of quantity of light emitted at a specific time after agonist mixing using luciferin and luciferase.

Another potential measurement is to determine the amount of extracellular platelet-release-reaction product (e.g., ATP) secreted due to the agonist, then lyse the platelets with detergent such as TRITON X-100 or SDS, and determine the extracellular platelet-release-reaction product after platelet lysis, which represents the total cellular product. The measurement and standard value can be the difference in product (e.g., ATP) concentration before and after detergent lysis, or the ratio of product concentration before cell lysis to product concentration after cell lysis. That difference or ratio measurement can be compared between blood treated with the COX1 inhibitor (the measurement) and blood not treated with the COX1 inhibitor (the standard).

In a particular embodiment, the standard value is determined by a method involving: (a) collecting platelet-containing standard blood from the mammal; (b) diluting the standard blood; (c) mixing the standard blood with the COX1-dependent platelet agonist to generate agonist-activated standard blood; and (d) monitoring extracellular ATP in the agonist-activated standard blood to generate the standard value, wherein the step of monitoring extracellular ATP involves (i) adding luciferin and luciferase to the standard blood, and (ii) monitoring light produced by the luciferase; wherein the standard blood is not treated with the COX1 inhibitor.

In a particular embodiment of that method, luciferin and luciferase are added to the standard blood before mixing the standard blood with the agonist (e.g., arachidonic acid). In another embodiment, they are added after mixing the standard blood with agonist.

Thus, in one embodiment, a result of assaying for the extracellular platelet-release-reaction product (e.g., ATP) in agonist-activated COX1-inhibitor-treated blood is compared with a result obtained using blood not treated with the COX1 inhibitor, preferably from the same individual.

In one embodiment, a result of assaying for the extracellular platelet-release-reaction product in arachidonic-acid-activated aspirin-treated blood is compared with a result obtained using non-aspirin-treated blood, preferably from the same individual.

The results from COX1-dependent agonist treatment can also be compared to results obtained using an agonist that is not COX1 dependent. For instance, the amount of extracellular platelet-release-reaction product in arachidonic-acid-activated COX1-inhibitor-treated blood can be compared with the amount of extracellular platelet-release-reaction product in thromboxane-A₂-activated COX1-inhibitor-treated blood. Thromboxane A₂ is the end product of the cyclooxygenase-1 pathway, the target of aspirin. So thromboxane A₂ will activate platelets to the same extent whether or not they are treated with a COX1 inhibitor such as aspirin and whether or not the platelets are sensitive to the COX1 inhibitor. In contrast, arachidonic acid will activate platelets to a much greater extent if the platelets are not treated with the COX1 inhibitor or are insensitive to the COX1 inhibitor.

Likewise, aspirin is also not expected to have as large an effect on the extent of platelet activation by certain other activators, including thrombin, collagen, and ADP, as it does on the extent of platelet activation by arachidonic acid. Thus, the amount of extracellular ATP induced by arachidonic acid activation can be compared to the amount of extracellular ATP induced by activation with thrombin, collagen, or ADP.

Accordingly, in certain embodiments of the invention, the standard value is determined by a method involving: collecting platelet-containing COX1-inhibitor-treated standard blood from the mammal; mixing the standard blood with a non-COX1-dependent platelet agonist to generate activated standard blood; and monitoring the extracellular platelet-release-reaction product (e.g., ATP) in the activated standard blood to generate the standard value. The non-COX1-dependent platelet agonist can be, for instance, thromboxane A₂, thrombin, collagen, or ADP.

Where the extracellular platelet-release-reaction product is ATP, a preferred method of detecting the ATP is by enzymatic methods, as described herein, in particular by the use of luciferin. ATP can also be detected, for example, by HPLC or gas chromatography, with or without mass spectrometry. Other extracellular platelet-release-reaction products can also be detected by HPLC, gas chromatography, and/or mass spectrometry. Some platelet-release-reaction products can be detected by enzymatic means, where for instance the release reaction product is a substrate for an enzymatic reaction, and the course of the enzymatic reaction is monitored by monitoring a product of the enzymatic reaction. Some extracellular platelet-release-reaction products, particularly proteins, are amenable to detection by immunologic means, such as ELISA.

The invention also provides a device, schematically shown in FIG. 3, having a fluid-tight material forming an assay chamber 11, a pump 20 for pumping fluids into the assay chamber, and a light detector 12 for detecting light emitted in the assay chamber. The device also includes a fluid-tight material forming a blood chamber 14 for holding blood 15, the blood chamber functionally linked to the pump 20. The device also includes a fluid-tight material forming an enzyme chamber 16 for holding a solution of a light-producing enzyme 17, the enzyme chamber functionally linked to the pump 20. The device also includes a fluid-tight material forming an agonist chamber 18 for holding a solution of a COX1-dependent platelet agonist 19, the agonist chamber functionally linked to the pump 20. The “solution” of a COX1-dependent platelet agonist can be pure agonist or undissolved agonist in suspension, but preferably is a true solution of the agonist (e.g., arachidonic acid) dissolved in water, ethanol, or another solvent.

In one embodiment, the device further includes a valve 13 functionally linked to the pump, the assay chamber, the blood chamber, the enzyme chamber, and the agonist chamber (FIG. 4). The valve can be, for instance, a multi-position valve.

In one embodiment, the device further includes a fluid-tight material forming a dilution medium chamber for holding dilution medium, the dilution medium chamber functionally linked to the pump.

Two or three of the assay chamber, the blood chamber, the enzyme chamber, and the agonist chamber can be the same chamber.

In one embodiment, all of the four chambers—the assay chamber, the blood chamber, the enzyme chamber, and the agonist chamber—are separate chambers.

The invention also provides a system for monitoring aspirin response involving all the elements of the device, along with a controller 21 for delivering to the assay chamber a predetermined volume of the blood, a predetermined volume of the light-producing enzyme solution, and a predetermined volume of the agonist solution; and a display 23 linked to the light detector for displaying light detector results (FIG. 5).

In particular embodiments, the predetermined volume of blood is less than 120, less than 100, less than 75, less than 40, less than 20, less than 12, or less than 10 microliters.

One embodiment of the invention provides a kit for determining response to a COX1inhibitor (e.g., aspirin) involving a COX1-dependent platelet agonist (e.g., arachidonic acid), an ATP-consuming enzyme, and instruction means.

In one embodiment of the kit, the enzyme is a light-producing ATP-consuming enzyme.

The invention will now be illustrated by the following non-limiting examples.

EXAMPLES Example 1 Assaying Platelet Aspirin Response Methods:

Volunteers who had not taken aspirin in the previous 24 hours underwent a finger prick to draw blood. Blood (2 μl) was diluted into 1 ml of buffer (PBS, 0.9% NaCl, 10 mM sodium phosphate, pH 7.0) in a clear test tube. An aliquot (15 μl) of luciferin/luciferase solution (containing 10 mg/ml luciferin and 10 μg/ml luciferase) as added to the diluted blood. The solution was mixed and placed in a Zylux FEMPTOMASTER FB12 photon counter. A baseline reading of the light emission was taken. The test tube was then withdrawn, and 5 μl of 15 mM arachidonic acid was added to the solution and the solution was mixed. The test tube was then reinserted in the photon counter and light emission readings were taken for approximately 2 to 4 minutes.

The volunteer then swallowed or chewed an aspirin (325 mg). A blood sample was taken, and the process was repeated. The results from blood drawn from an individual before and after taking aspirin were compared.

Results:

Time courses of light emission in the assays for three individuals before and after taking aspirin are shown in FIGS. 2A-C. In FIGS. 2A and 2C the slope of light emission vs. time after arachidonic acid is added to the sample is very steep for the no-aspirin sample but almost flat for the aspirin sample. The ratio of the no-aspirin maximal slope to the aspirin maximal slope is greater than 10:1. In contrast, results for the individual of FIG. 2B show a ratio of maximal slopes of the no-aspirin to the aspirin sample of slightly less than 2:1. Thus, the individual of FIG. 2B is less responsive to aspirin than the individuals of FIGS. 2A and 2C.

Discussion:

A very small amount of blood was used in this assay—2 μl—easily less than a drop of blood. Even less could be used. The limiting factor for using smaller volumes would probably be inaccuracy of measuring the volumes, which would cause imprecision in the assay results.

Lesser amounts of luciferin, luciferase, and arachidonic acid could be used than were used in this example. With lower amounts of luciferin or luciferase, the light emission would plateau sooner and at lower levels. The inventor believes that instead of the 15 mM arachidonic acid solution used in this example, 10 μM or less and possibly 1 μM or less arachidonic acid could be used without affecting the results.

To determine aspirin response, the data can be analyzed in several ways. The maximal slopes of the no-aspirin and aspirin samples can be compared. The peak light emission levels can be compared. The light emission at a certain time after adding arachidonic acid to the blood, e.g., 2 minutes, can be compared. Or a difference in light emission levels can be calculated for each sample and then compared, e.g., light emission at 2 minutes after adding arachidonic acid minus emission at 10 seconds after adding arachidonic acid or minus emission before adding arachidonic acid.

Example 2 An Apparatus for Monitoring Aspirin Response that Pumps Fluids into a Cuvette

The apparatus is shown in FIG. 6. Blood is diluted and stored in a diluted blood chamber or container 14. Firefly luciferin and luciferase are stored in a firefly extract container 16. Arachidonic acid is stored in a third container, an arachidonic acid container 18. Tubing 23 connects the solutions in each container to a bi-directional pump 20. The tubing to the three containers merges together before the pump, so that fluid is pumped by the pump simultaneously from all three containers and mixed together. If the tubing to each container is the same diameter, equal volumes are pumped from each container. By using tubing of unequal diameters to each container, the volume drawn from each container relative to the others can be controlled. The drawn fluids come together in the merged section of the tubing and are pulled by the pump 20 past a check valve 13. After the check valve the fluids are pumped by the bidirectional pump to a reaction cuvette 11 positioned within a photon counter 12 such as a photomultiplier tube. In the reaction cuvette 11, the fluids are further mixed, either by brownian motion or by a mechanical mixer, and the photons emitted are counted by the photon counter.

The pump and photon counter are preferably microprocessor controlled.

Example 3 Fluid Injection Analysis and Sequential Injection Analysis

A typical fluid injection analysis (FIA) manifold includes a pump, injection valve, photon counter, and tubing. The pump is used to propel one or more streams through the photon counter via a narrow-bore (0.5-0.8 mm ID) tubing. These streams may be reagents or buffer. The injection valve is used to periodically introduce a small volume (generally less than 100 μl) sample of one reagent into the carrier stream. As the sample is carried to the detector, the fluid dynamics of flow through a narrow-bore tubing mixes sample and carrier, leading to the reaction to form a detectable species (in this case light emission). This species is sensed by the detector as a transient peak. The height and area of the peak are proportional to concentration and are used to quantify the concentration of the species being determined by comparison to samples of known concentration (a calibration curve). Thus, for instance, blood, dilution buffer, and luciferin/luciferase can be premixed in the carrier stream, and arachidonic acid can be the injectable reagent added last to start the reaction.

In sequential injection analysis, a selection valve and a bidirectional pump are used to draw up small volumes of sample and reagents, and then propel them through a coil to a detector. Again the process causes mixing of the sample and reagent segments leading to chemistry that forms a detectable species before reaching the detector.

A type of sequential injection analysis device that could be adapted for use in the invention is described in U.S. Pat. No. 6,716,391.

Information and supplies for fluid injection analysis and sequential injection analysis are available at www.globalfia.com, Global FIA, Inc., Fox Island, Wash.

All cited patents, patent-related documents, and other references are hereby incorporated by reference. 

What is claimed is:
 1. A device for monitoring cyclooxygenase-1 inhibitor response comprising: a fluid-tight material forming an assay chamber; a pump functionally linked to the assay chamber for pumping fluids into the assay chamber; a light detector functionally linked to the assay chamber for detecting light emitted in the assay chamber; a fluid-tight material forming a blood chamber for holding blood, the blood chamber functionally linked to the pump; a fluid-tight material forming an enzyme chamber for holding a solution of a light-producing ATP-consuming enzyme, the enzyme chamber functionally linked to the pump; and a fluid-tight material forming an agonist chamber for holding a solution of a cyclooxygenase-1-dependent platelet agonist, the agonist chamber functionally linked to the pump.
 2. A system for monitoring cyclooxygenase-1-inhibitor response comprising: a fluid-tight material forming an assay chamber; a pump functionally linked to the assay chamber for pumping fluids into the assay chamber; a light detector functionally linked to the assay chamber for detecting light emitted in the assay chamber; a fluid-tight material forming a blood chamber for holding blood, the blood chamber functionally linked to the pump; a fluid-tight material forming an enzyme chamber for holding a solution of a light-producing ATP-consuming enzyme, the enzyme chamber functionally linked to the pump; a fluid-tight material forming an agonist chamber for holding a solution of a cyclooxygenase-1-dependent platelet agonist, the agonist chamber functionally linked to the pump; a controller coupled to the pump and programmed to deliver to the assay chamber a predetermined volume of the blood, a predetermined volume of the light-producing enzyme solution, and a predetermined volume of the agonist solution; and a display operably coupled to the light detector for displaying results from the light detector.
 3. The system of claim 2, further comprising a valve functionally linked to the pump, the assay chamber, the blood chamber, the enzyme chamber, and the agonist chamber.
 4. The system of claim 2, wherein the predetermined volume of blood is less than 40 μl. 